Hrev_master


[Dermatology Reports 2009; 1:e1] [page 1]

Tight junctions in Hailey-Hailey
and Darier’s diseases
Laura Raiko,1 Pekka Leinonen,2,3
Päivi M. Hägg,3 Juha Peltonen,4
Aarne Oikarinen,3 Sirkku Peltonen1
1Department of Dermatology, University
of Turku and Turku University Central
Hospital, Turku, Finland; 2Department of
Anatomy and Cell Biology and
3Department of Dermatology, University
of Oulu, Oulu, Finland; 4Institute of
Biomedicine, Department of Anatomy,
University of Turku, Turku, Finland

Abstract 

Hailey-Hailey disease (HHD) and Darier’s
disease (DD) are caused by mutations in Ca2+-
ATPases with the end result of desmosomal
disruption and suprabasal acantholysis. Tight
junctions (TJ) are located in the granular cell
layer in normal skin and contribute to the epi-
dermal barrier. Aberrations in the epidermal
differentiation, such as in psoriasis, have been
shown to lead to changes in the expression of
TJ components. Our aim was to elucidate the
expression and dynamics of the TJ proteins
during the disruption of desmosomes in HHD
and DD lesions. Indirect immunofluorescence
and avidin-biotin labeling for TJ, desmosomal
and adherens junction proteins, and subse-
quent analyses with the confocal laser scan-
ning microscope were carried out on 14 HHD
and 14 DD skin samples. Transepidermal water
loss (TEWL) was measured in normal and
lesional epidermis of nine HHD and eight DD
patients to evaluate the function of the epider-
mal barrier in HHD and DD skin. The localiza-
tion of TJ proteins claudin-1, claudin-4, ZO-1,
and occludin in perilesional HHD and DD epi-
dermis was similar to that previously described
in normal skin. In HHD lesions the tissue dis-
tribution of ZO-1 expanded to the acantholytic
spinous cells. In agreement with previous find-
ings, desmoplakin was localized intracellularly.
In contrast claudin-1 and ZO-1 persisted in the
cell-cell contact sites of acantholytic cells.
TEWL was increased in the lesional skin. The
current results suggest that TJ components fol-
low different dynamics in acantholysis of HHD
and DD compared to desmosomal and
adherens junction proteins.  

Introduction 

Hailey-Hailey disease (HHD, OMIM 16960)
and Darier’s disease (DD, OMIM 124200) are

rare blistering skin diseases inherited as an
autosomal dominant trait. HHD results in
mutations in the ATP2C1 gene, which
encodes the Golgi secretory pathway
Ca2+/Mn2+ ATPase (hSPCA1).1,2 DD is caused
by mutations in the ATP2A2 gene encoding
Ca2+-ATPase type 2 (SERCA2, sarcoplasm-
ic/endoplasmic reticulum Ca2+-transport
ATPase isoform 2b).3 The most prominent
common epidermal histological feature of DD
and HHD is suprabasal acantholysis, which
results from desmosomal disintegration. In
addition DD and HHD epidermis show differ-
entiation and keratinization defects.4-6

Specifically transition of keratin 14 to keratin
10 is abnormal as demonstrated by the pres-
ence of suprabasal keratinocytes expressing
both cytokeratins that usually are exclusive in
normal epidermis.6 Although the primary
abnormalities in calcium metabolism in HHD
and DD are known, the sequence of events
leading to acantholysis is not understood fully
yet.

In normal human epidermis, tight junc-
tions (TJ) are located in the granular layer7,8

where they contribute to the epidermal barri-
er function, especially the diffusion of water
from inside out.9-11 The most important trans-
membrane proteins of epidermal TJ are the
members of the claudin family; namely
claudins-1 and -4, which are expressed in all
vital epidermal layers.8,12 Transmembrane pro-
tein occludin and intracellular linking mole-
cule zonula occludens protein 1 (ZO-1) are
restricted to the granular layer normally.7

Previously we have shown that abnormal epi-
dermal differentiation is associated with dis-
turbances in distribution of TJ proteins.13

Examples of aberrant differentiation include
psoriatic epidermis and hypertrophic edges of
healing blisters, which show spreading of ZO-
1 and occludin to the acanthotic spinous cell
layers.7,13,14 Up-regulation of ZO-1 and occludin
is reversible and disappears during the heal-
ing of the psoriasis lesion.13 Regulation of TJ
proteins in epidermis is not well known but
the presence of TJ in the granular cell layers
suggests that the prerequisite for the forma-
tion of TJ is high extracellular calcium con-
centration. In fact studies on cultured ker-
atinocytes have shown that development of TJ
is calcium-inducible.7,15 We have demonstrat-
ed recently that in HHD and DD lesions the
calcium concentration in the basal layer is
lower than in normal skin.6 In addition to
being decreased in the basal cells in the
lesional HH and DD epidermis, the calcium
content was decreased in non-lesional DD
epidermis, probably linking to the keratiniza-
tion defect seen especially in DD.6

The localization of adherens junction and
desmosomal proteins in acantholytic lesions
of DD and HHD has been studied in detail
previously.16 However the dynamics of TJ pro-

teins has not been studied in acantholysis.
Studies on epidermal cadherin knockout mice
suggest the importance of cadherins in
assembly and/or stability of TJ and desmo-
somes.17,18 Thus desmosomes and TJ seem to
be at least partly co-regulated.

The aims of this study were: (1) to eluci-
date the role of TJ in the epidermal barrier in
blistering disease; (2) to study the localiza-
tion of TJ in an abnormal epidermal calcium
gradient; (3) to see whether the aberrant dif-
ferentiation in DD has an effect on TJ in the
analogy of psoriatic skin and healing wounds;
(4) to compare the dynamics of TJ compo-
nents to that of desmosomal and adherens
junction proteins at the cellular level in the
acantholytic process. Specifically we investi-
gated the localization of TJ components
claudin-1, claudin-4, ZO-1, and occludin in
frozen and paraffin-embedded skin of 14 HHD
and 14 DD patients using commercial anti-
bodies for indirect immunofluorescence and

Dermatology Reports 2009; volume 1:e1

Correspondence: Laura Raiko, Department of
Dermatology, University of Turku, 20520 Turku,
Finland. E-mail: laura.raiko@utu.fi

Key words: adherens junction, claudin, Darier-
White disease, tight junction, zonula occludens
protein 1. 

Acknowledgments: we thank Dr Lauri Talve,
Department of Pathology, Turku University
Central Hospital for providing the archival tissue
material. This study was supported financially by
grants from the Finnish Medical Foundation,
Finnish Cultural Foundation, Academy of Finland,
the Turku University Foundation, the Southwest
Finland Hospital District, and Northern
Ostrobothnia Hospital District, Finland. 

Contributions: LR, immunolabeling, confocal
microscopy, writing the manuscript, and design-
ing the figures; PL, TEWL measurements,
immunolabeling for frozen sections; PMH, obtain-
ing patient samples in Oulu, TEWL measure-
ments; JP, writing the manuscript and supervising
the work; AO, patient samples and supervising the
work in Oulu; SP, coordinating the work and par-
ticipating in all parts except TEWL measurements. 

Conflict of interest: the authors reported no con-
flicts of interest.

Received for publication: 1 October 2009.
Revision received: 2 November 2009.
Accepted for publication: 3 November 2009.

This work is licensed under a Creative Commons
Attribution 3.0 License (by-nc 3.0).

©Copyright L. Raiko et al., 2009
Licensee PAGEPress, Italy
Dermatology Reports 2009; 1:e1
doi:10.4081/dr.2009.e1

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[page 2] [Dermatology Reports 2009; 1:e1]

avidin-biotin immunolabeling. Co-localiza-
tion of TJ proteins with adherens junction
and desmosomal components was demon-
strated using the confocal laser scanning
microscope. In addition transepidermal water
loss (TEWL) was elucidated by measuring
TEWL in apparently normal and lesional HH
and DD skin. The results showed that in both
diseases the tissue localization of TJ proteins
remained apparently normal in the lesional
and perilesional epidermis, while acantholy-
sis was associated with changes in the distri-
bution of TJ proteins at the cellular level. 

Materials and Methods

Biopsy samples
The skin biopsies were taken at the

Department of Dermatology, Turku University
Central Hospital and the Department of
Dermatology, Oulu University Hospital,
Finland, with approval of the Ethical
Committee of the Southwest Finland Hospital
District and the Joint Ethical Committee of the
Oulu University Hospital, respectively. The
diagnosis of DD or HHD was based on clinical
appearance and histological diagnosis. The
patients gave their written consent. Four-mil-
limeter skin biopsies were taken from appar-
ently healthy skin and lesional areas in eight
DD patients aged 35-69 years and nine HHD
patients aged 45-80 years. In addition three
patients with DD and three patients with HHD
gave biopsies from lesional skin only. Paraffin-
embedded skin biopsies of four HHD patients
and five DD patients were obtained from the
Department of Pathology, Turku University
Central Hospital. Three control samples were
obtained from otherwise healthy patients
undergoing plastic surgery. The fresh skin
samples were frozen in liquid nitrogen or in
isopentane cooled in liquid nitrogen and
stored at -70°C or in liquid nitrogen. 

Primary antibodies 
The following primary antibodies were used:

affinity-purified rabbit polyclonal antibodies to
human claudin-1 (51-9000), ZO-1 (61-7300),
and occludin (71-1500); and mouse monoclon-
al antibodies to human claudin-4 (18-7341), E-
cadherin (33-4000), and ZO-1 (33-9100), all
from Zymed Laboratories Inc., South San
Francisco, CA, USA. Mouse monoclonal anti-
body to β-catenin (M3539) was purchased
from Dako (Glostrup, Denmark).
Nonimmunized mouse (2025) and rabbit
(2027) IgG were purchased from Santa Cruz
Biotechnology Inc., (Santa Cruz, CA, USA). All
antibodies against junctional proteins recog-
nized intracellular epitopes. 

Indirect immunofluorescence labeling 
Punch biopsy samples were cut into 7 µm

cryosections, mounted on silanated glass
slides, and fixed in 100% methyl alcohol at 
-20°C for 10 min. To prevent nonspecific bind-
ing, the samples were preincubated in 1%
bovine serum albumin (BSA) in phosphate
buffered saline (PBS) for 15 min. Antibodies
were diluted in 1% BSA-PBS, and incubated on
the samples at 4°C for 20 h. Either primary
antibodies were used alone or antibodies
raised in mouse and rabbit were mixed for
double labeling. Following five 5-min washes
in PBS, the samples were incubated with sec-
ondary antibodies and Hoechst nuclear stain
(dilution 1:10,000) at 20°C for 1 h. Secondary
antibodies used were Alexa Fluor 568 conjugat-
ed goat anti-rabbit IgG (A11011) or Alexa Fluor
488 conjugated goat anti-mouse IgG (A11029)
from Molecular Probes Inc. (Eugene, OR,
USA). In double labeling the secondary anti-
bodies for mouse and rabbit were mixed. The
samples were washed in PBS, dipped in dou-
ble-distilled water and mounted with Glycergel
(Dako, Glostrup, Denmark). In control immuno-
reactions primary antibodies were replaced
with 1% BSA-PBS or nonimmunized mouse or
rabbit IgG.  

Avidin-biotin immunolabeling of
paraffin-embedded tissues

Formalin-fixed and paraffin-embedded skin
specimens were immunolabeled with the
avidin-biotin method. The sections were cut
and mounted on SuperFrost Plus microscope
slides (Menzel-Gläser; Braunschweig,
Germany), deparaffinized, and hydrated in
descending ethanol series. To retrieve TJ anti-
gens ZO-1 and claudin-1, the samples were
boiled for 10 min in a microwave oven in 10
mM Tris, 1 mM ethylene diamine tetra-acetic
acid (EDTA), pH 9, and subsequently cooled in
the same solution at room temperature for 30
min. Endogenous peroxidase activity was
quenched by treating the sections in 0.3% H2O2
for 30 min. To prevent nonspecific binding the
sections were incubated in horse serum dilut-
ed in PBS. Antibodies to TJ were diluted in PBS
supplemented with 1% BSA and incubated on
the samples overnight at 4ºC. The bound anti-
bodies were visualized using the appropriate
avidin-biotin peroxidase kit (Vectastain;
Vector Laboratories, Burlingame, CA, USA)
with 3.3’–diaminobenzidine tetrahydrochlo-
ride (DAB) as a chromogen (DAB peroxidase
substrate kit; Vector Laboratories). Sections
were counterstained with Mayer’s hema-
toxylin. In negative control reactions the pri-
mary antibody was replaced with 1% BSA-PBS.

Microscopy
All examples of indirect immunofluores-

cence labeling were photographed using the

confocal microscope. Confocal laser scanning
microscopy was carried out using a Zeiss LSM
510 META confocal microscope equipped with
argon-ion and helium-neon lasers (Zeiss;
Jena, Germany) and LSM 3.0 software. The
objectives were 40X (oil immersion, numeric
aperture 1.3) and 63X (oil immersion, numer-
ic aperture 1.4). For excitation, the 405-nm
line was used for Hoechst, the 488-nm line for
Alexa FluorTM 488, and the 543-nm line for
Alexa FluorTM 568 and Cy3. The images were
saved in an LSM image browser program and
exported to Adobe Photoshop in jpg format.

TEWL measurements 
The VapoMeter with a closed cylindrical

chamber (Delfin Technologies Ltd, Kuopio,
Finland) was used for TEWL analyses. TEWL
was measured from lesional skin of nine
patients with HHD and eight patients with DD.
Measurements were obtained from lesional
and a corresponding healthy abdominal skin
area of each patient. In HHD patients lesional
areas included axillary (6), groin (1), leg (1),
and chest (1) areas, while all lesional values
from DD patients were measured from the
chest (8) area. The average values were calcu-
lated for normal and lesional skin. 

Results 

To investigate the function of the epidermal
barrier in HHD and DD, TEWL was measured
in nine patients with HHD and eight patients
with DD. The values of non-lesional and
lesional skin were compared. The results
showed that TEWL in lesional HHD and DD
areas was increased four- and three-fold,
respectively, compared to the normal skin. The
average TEWL for non-lesional HHD skin was
12.4, while the average TEWL value for lesion-
al skin was 44.6. In non-lesional DD skin the
average TEWL value was 17.8, while in the
lesional skin the average value was 50.0. The
p-values were calculated using the t-test for
independent samples, and resulted in a p-value
of <0.01 for both diseases (Figure 1). 

The localization of TJ components claudins-
1 and -4, ZO-1, and occludin in frozen and
paraffin-embedded skin of 14 cases of HHD
and 14 cases of DD was demonstrated using
indirect immunofluorescence and avidin-
biotin immunolabeling. The results showed
that the localization of TJ proteins in the
healthy looking epidermis in both diseases
was similar to that of the control skin. The
expression of TJ proteins remained normal in
the vicinity of the lesions. 

In HHD lesions typical suprabasal blistering
was observed. Groups of acantholytic cells
were noted in the blister fluid (Figure 2a-e). In
DD lesions characteristic acanthosis and acan-

Article

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[Dermatology Reports 2009; 1:e1] [page 3]

tholysis were detected (Figure 2f-j). In HHD
and DD samples ZO-1 was located in the blis-
ter roof (Figure 2b, g). In addition, in HHD ZO-
1 was seen in the remaining cell-cell contacts
of acantholytic spinous cells (Figure 2b).
Occludin was present in the intercellular junc-
tions of the granular cell layer located in the
blister roof (Figure 2c, h). Claudin-1 was
detected in all living cell layers (Figure 2d, i),
the basal cell layer being only faintly labeled.
Claudin-4 was localized mainly in the upper
epidermis (Figure 2e, j). To conclude, the gen-
eral distribution of TJ proteins occludin, and
claudin-1 and -4 corresponded to that
described earlier for normal skin. Thus the
acanthosis of DD could not be shown to induce
spreading of TJ to the spinous cell layers. 

To correlate the dynamics of TJ proteins
with that of desmosomal and adherens junc-
tion proteins, we double-labeled the sections
with antibodies to TJ proteins and desmo-
plakin, β-catenin, or E-cadherin. The antibody
recognizing the intracellular part of E-cad-
herin showed labeling of the intercellular con-
tacts in the acantholytic cells (Figure 2c, h).
This finding was in accordance with a previous
study.16 Desmoplakin was co-localized with
claudin-1 in the granular cell layer (Figure 2d,
i). In acantholytic cells desmoplakin showed a
diffuse cytoplasmic pattern while claudin-1
stayed in the remaining intercellular contacts
(Figure 2d). The co-localization of TJ proteins
with β-catenin, desmoplakin, and E-cadherin
in acantholytic cells was studied in more detail
in the HHD lesions (Figure 3). Double labeling
for ZO-1 and β-catenin revealed the presence
of both proteins in the cell periphery, although
some cytoplasmic ZO-1 labeling was noted as
well (Figure 3a). Double-labeling for claudin-1
with β-catenin revealed localization of both
proteins at the plasma membrane (Figure 3b).
Plenty of cytoplasmic β-catenin was seen in
acantholytic cells (Figure 3a, b), thus suggest-
ing that claudin-1 and β-catenin follow differ-
ent patterns in acantholysis. In addition to
being present in intercellular contacts,
claudin-1 was seen in the periphery of some
cells without an apparent contacting cell
(Figure 3c). Double labeling of claudin-1 and
desmoplakin also demonstrated different
dynamics of these proteins: claudin-1
remained at the plasma membrane of the
intercellular contacts while desmoplakin was
diffusely distributed in the cytoplasm. In acan-
tholysis the cells gradually lost contacts with
almost all the neighboring cells. During this
process claudin-1 finally disappeared from the
plasma membrane. However no clear cytoplas-
mic redistribution of claudin-1 could be seen.
Claudin-1 co-localized with E-cadherin in the
granular cell layer as well as in some intercel-
lular contacts of the acantholytic cells (Figure
3d). 

Article

Figure 1. Average TEWL values
of nine patients with Hailey-
Hailey disease (HHD) and
eight patients with Darier’s dis-
ease (DD). Lesional skin shows
three- to four-fold higher
TEWL values compared to the
non-lesional skin. HHD non-
lesional (12.4) compared to
lesional (44.6): p<0.01; DD
non-lesional (17.8) compared
to lesional (50.0): p<0.01. 

Figure 2. Hailey-Hailey dis-
ease (HHD) (a-e) and Darier’s
disease (DD) (f-j) lesions
immunolabeled for tight junc-
tion proteins claudin-1 (a, f ),
ZO-1 (b, g), and claudin-4 (e,
j); double labeling for E-cad-
herin and occludin (c, h), and
desmoplakin and claudin-1
(d, i). In (a) the inset is a con-
trol without any primary anti-
body. Avidin-biotin immuno-
labeling visualizes the
suprabasal blisters (asterisks)
in lesions of both diseases (a,
f ). Claudin-1 is expressed in
all epidermal cell layers (a, f ).
ZO-1 localizes to the upper
epidermis and acantholytic
cells in the HHD blister (b)
while in DD, ZO-1 is
expressed only in the granular
cell layer (g). Occludin (red) is
restricted to the granular cell
layer in both diseases, while E-
cadherin (green) is seen in
intercellular junctions in all
epidermal cell layers (c, h).
Claudin-1 and desmoplakin
are visible in all epidermal cell
layers (d, i). Claudin-4 local-
izes to the upper epidermis
and acantholytic cells in the
Hailey-Hailey blister and in
DD (e, j). Scale bar: 100 µm
in (a), (c), (e), (f ), (h), (i) and
(j); 50 µm in (b), (d) and (g).

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[page 4] [Dermatology Reports 2009; 1:e1]

Discussion

Based on genetically engineered mouse
models, TJs are known to contribute to the epi-
dermal barrier by regulating the TEWL.9 In the
present study, TEWL was measured in normal
and lesional HHD and DD skin. The results
showed that TEWL in lesional areas was
increased four- and three-fold, respectively,
compared to the non-lesional skin, although
the granular cell layer in the blistering area
had all the elements needed for complete TJs;
namely ZO-1, occludin, and two claudins.
Excess evaporation of water apparently takes
place through the broken blisters.

The formation of TJ in vitro is dependent on
external calcium concentration.7,8,15 Here we
investigated TJ in diseases in which the epi-
dermal calcium gradient is aberrant, which
might have an impact on the expression of TJ
proteins. The results showed that ZO-1 was
present in acantholytic suprabasal cells unlike
in non-lesional epidermis, where ZO-1 was
detected only in the granular cell layer. The
expression of all the other TJ proteins studied
remained essentially the same in the tissue
level compared to the non-lesional skin. Thus
the expression of ZO-1 can be speculated to
show different regulation compared to the
other TJ components studied. Aberrant epider-
mal differentiation previously has been shown
to change the expression pattern of TJ pro-
teins, ZO-1 in particular. Specifically healing of
an experimental wound leads to epidermal
hypertrophy, which displays an intense expres-
sion of ZO-1.14 In psoriasis acanthosis is asso-
ciated also with expression of ZO-1 in the spin-
ous cell layers.13 In contrast acanthosis of DD
epidermis was characterized with the lack of
ZO-1 in the spinous cells. This suggests that
the epidermal keratinocytes of DD follow dif-
ferent regulation of TJ components compared
to psoriasis. In addition the expression of ZO-
1 can be seen as a sensitive indicator of abnor-
mal differentiation. 

This study compared the dynamics of TJ pro-
teins with desmosomal and adherens junction
proteins at a single cell level. Previously it has
been shown that intra- and extracellular
domains of desmosomal cadherins and E-cad-
herin dissociate, and desmoplakin is internal-
ized in acantholytic cells in HHD and DD.4,16 The
present evidence suggests that TJ components
claudin-1, ZO-1, and occludin have somewhat
different dynamics in acantholysis compared to
desmosomal and adherens junction proteins.
For instance, desmoplakin exhibited a diffuse
cytoplasmic distribution in the acantholytic
cells while TJ proteins claudin-1 and occludin
remained in the cell-cell contact sites. Claudin-
1 was seen even in the free cell border of some
cells that were not in contact with neighboring
cells. The absence of cytoplasmic claudin-1 in

the acantholytic cells may be because of the
fact that it remains in the cell border or it is
rapidly degraded if internalized. The intracellu-
lar plaque protein ZO-1 was present in the
remaining intercellular contacts of the acan-
tholytic cells, but was not detectable in the free
cell borders. In contrast to claudin-1, some cyto-
plasmic ZO-1 could be seen. 

To conclude, in HHD and DD lesions the
abnormalities in the calcium gradient and epi-
dermal differentiation have little effect on the
expression of TJ proteins at the tissue level,
while the acantholytic process merely has an
impact on the dynamics of existing proteins at
the single cell level. 

References 

1. Sudbrak R, Brown J, Dobson-Stone C, et al.
Hailey-Hailey disease is caused by muta-

tions in ATP2C1 encoding a novel Ca(2+)
pump. Hum Mol Genet 2000;9:1131-40.  

2. Hu Z, Bonifas JM, Beech J, et al. Mutations
in ATP2C1, encoding a calcium pump,
cause Hailey-Hailey disease. Nat Genet
2000;24:61-5. 

3. Sakuntabhai A, Ruiz-Perez V, Carter S, et
al. Mutations in ATP2A2, encoding a Ca2+
pump, cause Daries disease. Nat Genet
1999;21:271-7.

4. Burge SM, Garrod DR. An immunohisto-
logical study of desmosomes in Darier’s
disease and Hailey-Hailey disease. Br J
Dermatol 1991;124:242-51.

5. Foggia L, Hovnanian A. Calcium pump dis-
orders of the skin. Am J Med Genet C
Semin Med Genet 2004;131C:20-31.   

6. Leinonen PT, Hägg PM, Peltonen S, et al.
Re-evaluation of the normal epidermal cal-
cium gradient, and analysis of calcium lev-
els and ATP receptors in Hailey-Hailey and
Darier epidermis. J Invest Dermatol 2009;
129:1379-87. 

Article

Figure 3. Acantholytic cells in Hailey-Hailey disease (HHD) lesions, double immunola-
beled for TJ proteins and adherens junction or desmosomal components. ZO-1 (red) and
β-catenin (green) are present in some of the remaining intercellular junctions, while both
proteins can be detected intracellularly and in plasma membranes not in contact with
neighboring cells (arrows) (a). Claudin-1 and β-catenin in the cell-cell contacts (b).
Claudin-1 is seen in the plasma membranes of cells not in contact with the neighboring
cells (arrows) (b,c). Double labeling for desmoplakin (green) and claudin -1 (red) shows
internalization of desmoplakin while claudin-1 stays in the plasma membrane (c). E-cad-
herin (green) and claudin-1 (red) are present at the plasma membrane (d). Scale-bar: 20
µm in (a), (b), (d); 50 µm in (c).

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[Dermatology Reports 2009; 1:e1] [page 5]

7. Pummi K, Malminen M, Aho H, et al.
Epidermal tight junctions: ZO-1 and
occludin are expressed in mature, develop-
ing, and affected skin, and in vitro differ-
entiating keratinocytes. J Invest Dermatol
2001;117:1050-8.

8. Brandner JM, Kief S, Grund C, et al.
Organization and formation of the tight
junction system in human epidermis and
cultured keratinocytes. Eur J Cell Biol
2002;81:253-63.

9. Furuse M, Hata M, Furuse K, et al.
Claudin-based tight junctions are crucial
for the mammalian epidermal barrier: a
lesson from claudin-1-deficient mice. J
Cell Biol 2002;156:1099-111.

10. Turksen K, Troy TC. Permeability barrier
dysfunction in transgenic mice overex-
pressing claudin 6. Development 2002;129:

1775-84.
11. Troy TC, Rahbar R, Arabzadeh A, et al.

Delayed epidermal permeability barrier
formation and hair follicle aberrations in
Inv-Cldn6 mice. Mech Dev 2005;122:805-
19.

12. Morita K, Miyachi Y. Tight junctions in the
skin. J Dermatol Sci 2003;31:81-9. 

13. Peltonen S, Riehokainen J, Pummi K, et al.
Tight junction components occludin, ZO-1,
and claudin-1, -4 and -5 in active and heal-
ing psoriasis. Br J Dermatol 2007;156:466-
72. 

14. Malminen M, Koivukangas V, Peltonen J,
et al. Immunohistochemical distribution
of the tight junction components ZO-1 and
occludin in regenerating human epider-
mis. Br J Dermatol 2003;149:255-60.

15. Yuki T, Haratake A, Koishikawa H, et al.

Tight junction proteins in keratinocytes:
localization and contribution to barrier
function. Exp Dermatol 2007;16:324-30.

16. Hakuno M, Shimizu H, Akiyama M, et al.
Dissociation of intra- and extracellular
domains of desmosomal cadherins and E-
cadherin in Hailey-Hailey disease and
Darier’s disease. Br J Dermatol 2000;142:
702-11. 

17. Muller SL, Portwich M, Schmidt A, et al.
The tight junction protein occludin and the
adherens junction protein alpha-catenin
share a common interaction mechanism
with ZO-1. J Biol Chem 2005;280:3747-56. 

18. Tinkle CL, Pasolli HA, Stokes N, et al. New
insights into cadherin function in epider-
mal sheet formation and maintenance of
tissue integrity. Proc Natl Acad Sci USA
2008;105:15405-10. 

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